Thermosonic-Adhesive Flip Chip Assembly for Advanced Microelectronic Packaging Andrew S. Holmes and Guangbin Dou Department of Electrical & Electronic Engineering Imperial College London In collaboration with: Sony*, GE Aviation Systems and Henkel *Sony Chemicals Europe and Sony Chemical & Information Device Corp IeMRC Conference, Loughborough, 21 st September 2011
Outline Background to project; aims & objectives Work to date Future plans Conclusions
Flip chip technologies Solder-based Controlled gap No gap control Non-conductive adhesive Adhesive-based Anisotropic conductive adhesive Isotropic conductive adhesive Metal-metal bond Direct thermocompression Thermosonic compression Mechanical contact Spring force; no intermediate layer
ACA packaging Advantages Low cost Low cure temperature High density assembly High flexibility Disadvantages Large joint resistances Reliability failures Source: Sony Chemical
Thermosonic flip chip Thermosonic bonding basic principle Metal-metal bond formed by combination of heat, pressure and ultrasonic energy Ultrasound allows bonding at lower temp and/or pressure than with thermo-compression Various materials systems e.g. Au-Au, Au-Al, Cu-Al History Used for wire bonding since mid 1960s serial process First applied to flip chip in late 1990s (gold stud bumps on chip pads) Previous work at Imperial College:* Advantages http://www.sound-gear.info Disadvantage Direct metal to metal bonding No additional bonding materials Low bond temp High density assembly Limited chip size *S. Gao & A. Holmes, IEEE TRANS. on ADVANCED PACKAGING, Vol. 29 (4), 2006
IeMRC project Project aim To introduce a thermosonic bonding step into ACA/NCA assembly in order to replace the mechanical contacts by metal-metal thermosonic bonds Objectives Demonstrate feasibility of TA assembly, both for NCA and ACA Optimize processes once established Examine electrical performance & reliability, and compare with traditional adhesive flip-chip processes Investigate feasibility of using low-cost ACA particles e.g. Cu, Al Apply the new technology to a demonstrator that can be functionally tested
Project tasks Alternative TA bonding materials Design & construction of TA flip chip bonder Thermo-sonic (TS) bonding of conductive particles in adhesive Demonstrator Project tasks Direct metal bump to metal pad TS bonding in adhesive Reliability tests Electrical measurements
Work to date TS bonder upgrade Flip chips and substrates Fast IR laser heating of flip-chip pick-up tool Vacuum substrate holder Other improvements to existing bonder Dummy flip chips with electrical test patterns Flex and glass substrates First trials with and without adhesive Chip to glass substrate (COG) Chip to flex substrate (COF) TA bonding materials Process for ACA with embedded gold cylinders First batch in fabrication
TS bonder upgrade TS bonder developed in earlier EPSRC project 40 W 60 khz ultrasonic transducer & horn Vacuum pick-up tool for chip Load cell for controlled bonding force Heated stage (up to 250 C) Substrate holding clamps Through-substrate alignment microscope Optical parallelism adjustment (± 1.5 µm for 3 3 mm 2 die) Additional facilities required for TA bonding Rapid heating & cooling to allow control over adhesive flow & curing Substrate chuck capable of handling Stainless rigid steel and stage flex substrates Typical ACA curing cycles
IR laser heating of pick-up tool Rationale Would like non-contact heating to avoid disturbance of ultrasonic path to tool Fibre-coupled IR lasers can provide highly localised heating Verification FEA carried out to establish laser power requirements and effect on transducer temp Temp profile at tool tip for 10 W point heat source Thanks to Dr Lu and Dr Yin of Greenwich University for assistance with FEA
IR laser heating of pick-up tool (2) Final solution Symmetrical heating by two 30 W, 970 nm fibre coupled laser diodes (DPSS pump lasers) Compressed air cooling Heating rate up to ~35 C/sec; cooling to -10 C/sec Fully interlocked, Class I enclosure (WIP!) Cooling nozzle Ultrasonic horn Brass cap TiC pick up tool Laser delivery block Stainless steel stage
Vacuum substrate holder Requirement Method for clamping substrates adequately for TS bonding Must be compatible with existing (through-substrate) alignment and co-planarity optics Solution Glass window with machined vacuum channels works well with both substrate types
Dummy flip chips Processing Chip fabrication (ECS Partners Ltd) Al metallisation over oxide Passivation SiO 2 /Si 3 N 4 (0.25/1µm) Dicing Bumping (in-house) Electrolytic Ni plating (4µm) Electrolytic Au plating (1µm) ^^ Enlarged view showing connections One electrical test group matched to the substrate pattern Chip size and structure 3 3 mm 2 chip with 88 I/Os, 100 µm pitch Bumps: Al/Ni/Au (1/4/1µm) 4.5 4.5 mm 2 chip with 144 I/Os Bumps: Al/Ni/Au (1/4/1µm)
Test substrates Substrate designs (both chip sizes) Flex substrates - PI/Cu/Ni/Au = 38/8/5/0.8 µm Glass substrates - Silica/Ni/Au = 500/5/1.0 µm Manufacturers Flex: Compass Technology Com. Ltd. Glass: in-house One electrical test group matched to the chip pattern Flex or Glass
Initial assembly trials Materials NCF (Sony MA101-40) or no adhesive Glass and flex substrates 3 3mm 2 chip size TS bonding here Conditions Film lamination: 0.2MPa @80ºC Final bonding force: 3.75 kg (43 gf/bump) Ultrasonic power/time: 16 W/300 ms COF bonding without NCF COF bonding with NCF COG bonding without NCF COG bonding with NCF
Results of initial trials Initial inspection First assemblies show some co-planarity errors needs optimization Also an alignment issue when using adhesive Electrical tests Four-wire measurement using test groups ~6 mω joint resistance achieved in TA bonding Joint resistance: TA<TS<ACA? TA may be lowest due to direct Au to Au welding & adhesive shrinkage? Graph shows selected individual tests
Results of initial trials (2) Inspection following disassembly Chip separated from substrate following dissolution of adhesive with acetone Some Au bump residue seen on substrate pad; torn from bump during disassembly suggests metal-metal weld Encouraging result but early days Optical image
Manufacture of TA bonding materials Seed layer and PR coating NCF placement PR developed Au stud electroplated PR removal Au seed layer dry etched Laser transfer Au studs on fused silica wafer Laser transfer onto Sony NCF TA bonding
Au stud fabrication Stud design Size: Ø10, 2.5µm high Pitch: 25 or 30µm; 6-9 studs/bump Trial fabrication Au seed layer on fused silica wafer: 200 nm Au stud electroplated at 3 ma/cm 2 Seed layer etching Sputter etching - 20 mins @ 200 W Etch rate ~10nm/min
Next steps Further assembly trials with Sony NCF/ACF materials Explore process parameters Optimise using joint resistance as key performance indicator TA bonding materials Complete and evaluate custom ACA (solid gold particles in NCF) Reliability tests (with GE Aviation Systems) Thermal and humidity tests Temperature cycling / thermal shock if time allows Joint resistance as main criterion
Conclusions Aiming to improve the performance of adhesive-based flip chip assembly by incorporation of thermosonic bonds If successful, proposed processes will expand the range of applications for adhesive assembly Work to date has focused on putting facilities and materials in place. Work on TA bonder has produced a highly versatile bond tool Now need to optimise processes and evaluate through performance and reliability testing